DE102019124291A1 - Arrangement for operating several air-liquid heat exchanger units connected in parallel - Google Patents

Abstract

The invention relates to an arrangement for operating several air-liquid heat exchanger units connected in parallel, each of the units having at least one electrically driven fan and an electrically controllable valve arranged in the liquid circuit, and the valve being actuatable primarily by at least one thermostat. According to the invention, each air-liquid heat exchanger unit has an additional switching device which superimposes the primary thermostat switching process and actuates and closes the relevant valve, with the detection of overheating or overheating caused by gas inclusion in the case of n with n ≥ 2 air-liquid heat exchanger units connected in parallel. In the event of an excess temperature in one of the air-liquid heat exchanger units, the remaining air-liquid heat exchanger units are briefly shut off by actuating the respective additional switching device, as a result of which the pressure increases and gas inclusions can be removed.

Description

The invention is based on an arrangement for operating several air-liquid heat exchanger units connected in parallel, each of the units having at least one electric motor-driven fan and an electrically controllable valve arranged in the liquid circuit, and the valve being primarily actuatable by at least one thermostat according to the preamble of Claim 1.

From the DE 33 25 230 C2 a water / sol-air heat exchanger is previously known, in which several pipe layers are combined to form a waterway to increase the flow rate and jump in height, each waterway being separately blockable and thus ventable via a water-side shut-off system with shut-offs.

According to CH 594 770 a device for filling and emptying heat exchangers is previously known.

According to the teaching there, shut-off valves are present in the drain line. When the heat exchanger is filled, the shut-off valve in the relevant drain line is closed, while the shut-off valve in the return line is opened and the shut-off valve in the feed line is kept closed. As a result, cooling water flows into the outlet floods of the heat exchangers via a return line, with the air before the rising water from the heat exchangers being displaced into the environment via vent valves.

The DE 199 53 612 A1 refers to heat exchangers with almost horizontal heat exchanger tubes, the surfaces of which are used for heat exchange. It is mentioned there that the heat exchanger tubes are combined to form groups of parallel tubes. The pipe group furthest above is provided for ventilation.

The DE 10 2009 011 797 B4 relates to a method for operating a cooling system, in which cooling energy is provided by means of a cold generating device and is supplied to at least one cooling station by means of a cooling circuit. If there is an air lock in the system, the cooling system can be vented by a corresponding control of a vent valve arranged in a vent line. The vent valve can be designed as a solenoid valve and can be operated manually or automatically.

According to the procedure for the reliable function of heat exchangers according to EP 0 865 602 B2 the design, dimensioning and mode of operation of the components of the heat exchanger through which liquid flows are coordinated in such a way that fully automatic venting of the components carrying the liquid can take place. In this regard, the device has several parallel components for heat transfer through which liquid flows. For complete venting of the components with height protrusions through which the liquid flows, especially in the case of hydraulic interconnection caused by countercurrent, the flow differential pressure is increased by a factor while maintaining the process-related liquid mass flow.

Basically, it should be noted that with several air-liquid heat exchangers that are connected in parallel, air inclusions occur more or less frequently in the heat exchangers. This is largely unproblematic under normal operating conditions. If, however, there is a high heat load, excess temperatures occur in those heat exchangers that are exposed to air. In these cases the fluid circuit is interrupted or disturbed.

In order to avoid the effects of air, it is known to provide vent valves at the highest point of corresponding heat exchanger systems. However, since the piping of the individual heat exchanger units within such a unit as well as the connecting piping is often designed to be complicated and structurally complex, it cannot be guaranteed that all the gas can be removed from the relevant system.

From the above, it is therefore the object of the invention to provide a further developed arrangement for operating several air-liquid heat exchanger units connected in parallel, which has a high level of operational reliability and thus failure safety, and which is quick, uncomplicated and also on site at the customer's premises can be safely vented. If possible, disassembly and assembly of the corresponding units should be avoided when used on site.

The object of the invention is achieved by the combination of features according to patent claim 1, the subclaims including at least useful configurations and developments.

Accordingly, an arrangement for operating a plurality of air-liquid heat exchanger units connected in parallel is assumed.

These are therefore n-air-liquid heat exchanger units, where n 2.

Each of the air-liquid heat exchanger units has at least one electric motor driven fan to flow through the heat exchanger. In addition, there is at least one electrically controllable valve arranged in the liquid circuit. This valve is operated primarily by at least one thermostat in order to influence the fluid circuit depending on the load applied.

According to the invention, each of the air-liquid heat exchanger units has an additional switching device, which superimposes the primary thermostat switching process and insofar actuates and closes or re-opens the valve in question, with n with n ≥ 2 air-liquid heat exchanger units connected in parallel with the Detection of an overheating caused by gas inclusion or an excess temperature of one of the air-liquid heat exchanger units, the remaining air-liquid heat exchanger units are briefly shut off by actuating the respective additional switching device.

This results in an increase in pressure and existing gas inclusions can be removed or driven out via a venting device known per se.

In one embodiment of the invention, the activation or deactivation of the additional switching device, that is to say the closing and / or opening process, can be signaled optically and / or acoustically. Because the additional switching device can be activated manually, the optical and / or acoustic signaling prevents one of the heat exchanger units from being inadvertently shut off for too long, resulting in a reduction in the performance of the entire system connected in parallel.

In a further development of the invention, a control device is provided which, after the respective switching devices have been triggered, cancels the resulting shut-off of the fluid circuits after a predetermined period of time or signals that this cancellation of the shut-off must be carried out by manually operating the corresponding switching devices.

The control device proposed according to the invention can be connected to a sensor system which determines whether and, if so, in which of the air-liquid heat exchanger units there are gas connections. This can automatically shut off the remaining air-liquid heat exchanger units for venting.

Each of the air-liquid heat exchanger units expediently has an excess temperature detection device, with one of the parallel-connected air-liquid heat exchanger units being defined as to be vented and, in this regard, the remaining n-air-liquid heat exchanger units being temporarily shut off.

It is within the meaning of the invention to retrofit known heat exchanger units with the switching device according to the invention in order to improve existing systems and to ensure easy venting and thus trouble-free operation. The switching device according to the invention is accessible to the service employee, but can be designed to be protected by arranging appropriate means in order to avoid inadvertent locking by unauthorized persons.

In a further development of the invention there is the possibility of signaling the blocking measure acoustically for the duration of the blocking for the purpose of venting, for example by means of a conspicuous beep. The service technician is reminded by this acoustic measure to restore the normal operating status after completing his service work.

The invention is to be explained in more detail below using an exemplary embodiment and a figure.

The figure shows a basic circuit diagram of the electrical means of the arrangement according to the invention, the actual air-liquid heat exchanger units with the related liquid-carrying elements being omitted.

According to the figure, there are initially two thermostat devices A1 and A2. These thermostat devices are used, on the one hand, to preset the temperature and, on the other hand, to set an excess temperature, that is to say to send out an alarm when this predetermined excess temperature is reached or exceeded.

For control purposes, the thermostat device A2 is connected to a solenoid valve Y1 and actuates this by switching the solenoid valve on and off in accordance with the specified temperature values.

An electric motor M1 is used to drive a ventilator or ventilator, which is otherwise not shown, to flow the heat exchanger, also not shown.

The capacities C1 and C2 are used to operate the fan motor with regard to the Start-up process or with a possible regulation of the fan speed.

X1 and X2 are connectors to allow easy interchangeability of corresponding assemblies in the event of service or repair work, but also to be able to loop in measuring and testing equipment.

The additional switching device S1 according to the invention is able to superimpose the function of the thermostat A2, that is to say, independently of a deactivation of the solenoid valve Y1 caused by the thermostat, for example, to stimulate it to close.

The switching device S1 also has an optical display L1, in particular a light-emitting diode, which is operated via a series resistor R1.

If the switching device S1 is actuated, the contacts 3 and 4 (BK) are closed and the solenoid valve Y1 is excited, with the result that the valve changes to the closed state.

The excess temperature, which is monitored by thermostat A1, is preset to 50 °, for example. The operating temperature, controlled and set via the thermostat A2, is, for example, 35 ° in a relevant preset.

The switching device S1 with the LED L1 is preferably arranged on the rear of the device of a corresponding air-liquid heat exchanger unit, not shown in the figure. Appropriate signaling can, however, also be provided on the front.

For the purpose of ventilation, all heat exchanger units are shut off with the help of the respective solenoid valves Y1 except for the one that has air pockets. This makes it possible to press the relevant heat exchanger unit free of air.

After this, this heat exchanger unit, which has just been released, is shut off and a corresponding further heat exchanger unit of the previously shut off units is opened in order to vent the same. This can be done successively until all of the n-type heat exchanger units are free of air. Particularly in the case of service, for example when a system is refilled, the possibility of individual electromechanical closing of the individual heat exchanger units is a great advantage.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 3325230 C2 [0002]
• DE 19953612 A1 [0005]
• DE 102009011797 B4 [0006]
• EP 0865602 B2 [0007]

Claims (5)

Arrangement for operating several air-liquid heat exchanger units connected in parallel, each of the units having at least one electrically driven fan (M1) and an electrically controllable valve (Y1) arranged in the liquid circuit and the valve (Y1) being primarily controlled by at least one thermostat (A2 ) can be actuated, characterized in that each air-liquid heat exchanger unit has an additional switching device (S1) which superimposes the primary thermostat switching process (A2) and actuates and closes the relevant valve (Y1), with n with n ≥ 2 air-liquid heat exchanger units connected in parallel with the detection of overheating caused by gas inclusion or an excess temperature of one of the air-liquid heat exchanger units, the remaining air-liquid heat exchanger units are briefly shut off by actuating the respective additional switching device (S1), which results in a pressure and gas inclusions can be removed. Arrangement according to Claim 1 , characterized in that the activation of the additional switching device (S1) can be signaled optically and / or acoustically. Arrangement according to one of the preceding claims, characterized in that a control device is provided which, after the triggering of the respective switching devices (S1), cancels the shut-off of the fluid circuits caused by this after a predetermined period of time. Arrangement according to Claim 3 , characterized in that the control device is connected to a sensor system which determines whether and, if so, in which of the air-liquid heat exchanger units there are gas inclusions in order to automatically trigger the shut-off of the remaining air-liquid heat exchanger units for ventilation. Arrangement according to one of the preceding claims, characterized in that each of the air-liquid heat exchanger units has an excess temperature detection device, wherein if excess temperature is detected in one of the air-liquid heat exchanger units connected in parallel, it is defined as to be vented and in this regard the remaining of the n air Liquid heat exchanger units are shut off briefly.

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